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Inductance

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... LC = 25330.3 / f 2 and L = 25330.3 / f 2 C and C = 25330.3 / f 2 L Impedance at Resonance In a series resonant circuit the impedance is at its lowest ... – PowerPoint PPT presentation

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Title: Inductance


1
Inductance
  • The property of inductance might be described as
  • "when any piece of wire is wound into a coil form
    it forms an inductance which is the property of
    opposing any change in current".

2
Inductance
  • Alternatively it could be said
  • "inductance is the property of a circuit by
    which energy is stored in the form of an
    electromagnetic field".

3
Inductance
  • We said a piece of wire wound into a coil form
    has the ability to produce a counter emf
    (opposing current flow) and therefore has a value
    of inductance.

4
Inductance
  • The standard value of inductance is the Henry, a
    large value which like the Farad for capacitance
    is rarely encountered in electronics today
  • Typical values of units encountered are
    milli-henries mH, one thousandth of a henry or
    the micro-henry uH, one millionth of a henry.

5
Inductance
  • A small straight piece of wire exhibits
    inductance (probably a fraction of a uH) although
    not of any major significance until we reach UHF
    frequencies.
  • The value of an inductance varies in proportion
    to the number of turns squared.

6
Inductance
  • If a coil was of one turn its value might be one
    unit.
  • Having two turns the value would be four units
    while three turns would produce nine units
    although the length of the coil also enters into
    the equation.

7
Inductance formula
  • The standard inductance formula for close
    approximation - imperial and metric is

8
Imperial measurements
  • L r2 X N2 / ( 9r 10len ) where L
    inductance in uH r coil radius in inches N
    number of turns len length of the coil in
    inches

9
Metric measurements
  • L 0.394r2 X N2 / ( 9r 10len ) where L
    inductance in uH r coil radius in centimetres
    N number of turns len length of the coil in
    centimetres

10
Reactance
  • Reactance is the property of resisting or
    impeding the flow of ac current or ac voltage in
    inductors and capacitors.
  • Note particularly we speak of alternating current
    only ac, which expression includes audio af and
    radio frequencies rf.

11
Reactance
  • NOT direct current dc.
  • This leads to inductive reactance and capacitive
    reactance.

12
Inductive Reactance
  • When ac current flows through an inductance a
    back emf or voltage develops opposing any change
    in the initial current.
  • This opposition or impedance to a change in
    current flow is measured in terms of inductive
    reactance.

13
Inductive Reactance
  • Inductive reactance is determined by the formula
  • 2 pi f L
  • where 2 pi 6.2832 f frequency in hertz
    and L inductance in Henries

14
Capacitive Reactance
  • When ac voltage flows through a capacitance an
    opposing change in the initial voltage occurs,
  • this opposition or impedance to a change in
    voltage is measured in terms of capacitive
    reactance.

15
Capacitive Reactance
  • Capacitive reactance is determined by the
    formula
  • 1 / (2 pi f C)
  • where 2 pi 6.2832 f frequency in hertz
    and C capacitance in Farads

16
Some examples of Reactance
  • What reactance does a 6.8 uH inductor present at
    7 Mhz? Using the formula above we get
  • 2 pi f L
  • where 2 pi 6.2832 f 7,000,000 Hz and L
    .0000068 Henries
  • Answer 299 ohms

17
Some examples of Reactance
  • What reactance does a 33 pF capacitor present at
    7 Mhz? Using the formula above we get
  • 1 / (2 pi f C)
  • where 2 pi 6.2832 f 7,000,000 Hz and C
    .0000000000033 Farads
  • Answer 689 ohms

18
Resonance
  • Resonance occurs when the reactance of an
    inductor balances the reactance of a capacitor at
    some given frequency.
  • In such a resonant circuit where it is in series
    resonance, the current will be maximum and
    offering minimum impedance.

19
Resonance
  • In parallel resonant circuits the opposite is
    true.
  • Resonance formula
  • 2 pi f L 1 / (2 pi f C)
  • where 2 pi 6.2832 f frequency in hertz L
    inductance in Henries and C capacitance in
    Farads

20
Resonance
  • Which leads us on to
  • f 1 / 2 pi (sqrt LC)
  • where 2 pi 6.2832 f frequency in hertz L
    inductance in Henries and C capacitance in
    Farads

21
Resonance
  • A particularly simpler formula for radio
    frequencies (make sure you learn it) is
  • LC 25330.3 / f 2
  • where f frequency in Megahertz (Mhz) L
    inductance in microhenries (uH) and C
    capacitance in picofarads (pF)

22
Resonance
  • Following on from that by using simple algebra we
    can determine
  • LC 25330.3 / f 2  and  L 25330.3 / f 2 C
     and  C 25330.3 / f 2 L

23
Impedance at Resonance
  • In a series resonant circuit the impedance is at
    its lowest for the resonant frequency
  • whereas in a parallel resonant circuit the
    impedance is at its greatest for the resonant
    frequency.
  • See figure.

24
Resonance in series and parallel circuits
25
Impedance
  • Electrical impedance describes a measure of
    opposition to alternating current (AC).
  • Electrical impedance extends the concept of
    resistance to AC circuits,

26
Impedance
  • describing not only the relative amplitudes of
    the voltage and current, but also the relative
    phases.
  • When the circuit is driven with direct current
    (DC) there is no distinction between impedance
    and resistance
  • the latter can be thought of as impedance with
    zero phase angle.

27
Impedance
  • The symbol for impedance is usually Z and it may
    be represented by writing its magnitude and phase
    in the form Zlt ?

28
Combining impedances
  • The total impedance of many simple networks of
    components can be calculated using the rules for
    combining impedances in series and parallel.

29
Combining impedances
  • The rules are identical to those used for
    combining resistances,
  • except that the numbers in general will be
    complex numbers.
  • In the general case however, equivalent impedance
    transforms in addition to series and parallel
    will be required

30
Series combination
  • For components connected in series, the current
    through each circuit element is the same
  • the total impedance is the sum of the component
    impedances

31
Impedance
32
Parallel combination
  • For components connected in parallel,
  • the voltage across each circuit element is the
    same
  • the ratio of currents through any two elements is
    the inverse ratio of their impedances

33
Parallel combination
34
Parallel combination
  • Hence the inverse total impedance is the sum of
    the inverses of the component impedances

35
Diodes
  • Diodes are semiconductor devices which might be
    described as passing current in one direction
    only.
  • The latter part of that statement applies equally
    to vacuum tube diodes.

36
Diodes
  • Diodes can be used as voltage regulators,
  • tuning devices in rf tuned circuits,
  • frequency multiplying devices in rf circuits,
  • mixing devices in rf circuits,
  • switching applications or can be used to make
    logic decisions in digital circuits.

37
Diodes
  • There are also diodes which emit "light", of
    course these are known as light-emitting-diodes
    or LED's.

38
Schematic symbols for Diodes
39
Types of Diodes
  • The first diode in figure is a semiconductor
    diode
  • Commonly used in switching applications
  • You will notice the straight bar end has the
    letter "k", this denotes the "cathode" while the
    "a" denotes anode.

40
Types of Diodes
  • Current can only flow from anode to cathode and
    not in the reverse direction, hence the "arrow"
    appearance.
  • This is one very important property of diodes

41
Types of Diodes
  • The second of the diodes is a zener diode which
    are fairly popular for the voltage regulation of
    low current power supplies.

42
Types of Diodes
  • The next is a varactor or tuning diode.
  • Depicted here is actually two varactor diodes
    mounted back to back with the DC control voltage
    applied at the common junction of the cathodes.
  • These cathodes have the double bar appearance of
    capacitors to indicate a varactor diode.

43
Types of Diodes
  • When a DC control voltage is applied to the
    common junction of the cathodes,
  • the capacitance exhibited by the diodes (all
    diodes and transistors exhibit some degree of
    capacitance) will vary in accordance with the
    applied voltage.

44
Types of Diodes
  • The next diode is the simplest form of vacuum
    tube or valve.
  • It simply has the old cathode and anode.
  • These terms were passed on to modern solid state
    devices.
  • Vacuum tube diodes are mainly only of interest to
    restorers and tube enthusiasts

45
Types of Diodes
  • The last diode depicted is a light emitting diode
    or LED.
  • A led actually doesn't emit as much light as it
    first appears,
  • a single LED has a plastic lens installed over it
    and this concentrates the amount of light.

46
Types of Diodes
  • Seven LED's can be arranged in a bar fashion
    called a seven segment LED display and when
    decoded properly can display the numbers 0 - 9 as
    well as the letters A to F.

47
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